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From the Edited Volume

1. Introduction

Sunitinib malate (Sutent, Pfizer inc., New York, NY) is an orally administered, multitargeted inhibitor of tyrosine kinases, including vascular endothelial growth factor (VEGF) receptor, platelet-derived growth factor (PDGF) receptor, stem cell factor receptor (KIT), fms-like tyrosine kinase (FLT) -3, CSF-1R, and RET. Since the introduction of sunitinib for patients with advanced renal tumor [1], significant objective responses of sunitnib have been revealed [2-6]. In a randomized, multicenter, phase III trial enrolled 750 patients with previously-untreated metastatic renal tumor to receive either sunitinib or interferon (IFN) -α, sunitinib was superior to IFN-α in the objective response rate (47% vs 12%), progression-free survival time (11.0 vs 5.0 months), and overall survival time (26.4 vs 21.8 months) [3, 4]. Also in a Japanese, multicenter, phase II trial enrolled 51 patients with first-line and pretreated metastatic clear-cell renal tumor to recieve sinitinib, significant responses of sunitinib have been reported that objective response rate was 52.9%, the median progression-free survival time was 12.2 and 10.6 months, and the median overall survival time was 33.1 and 32.5 months in first-line and pretreated patients, respectively [5, 6]. Sunitinib is approved worldwide for first-line treatment of advanced clear-cell renal tumor. However, approximately half of patients with advanced renal tumor do not see clinical benefits from sunitinib treatment. A prognostic marker is needed for selecting patients who will benefit most from sunitinib.

It has been advocated that the necessity of determining molecular and clinical biomarkers that may predict efficacy of sunitinib. The identification of biomarkers to predict response is urgently needed. This chapter provides a brief overview of the signaling pathways of renal tumors and introduces biomarkers to predict response to sunitinib of clinical variables.

2. Signaling pathways in renal tumors

Renal tumors originates from the tubular structures of the kidney and is calssified into four major histological cell types. Clear-cell renal tumor is the most common type, accounting for approximately 75% of all renal tumors. Other types are followed by papillary renal tumor (approximately 15%), chromophobe renal tumor (approximately 5%), and renal oncocytoma (approximately 5%) [7].

Alterations in proto-oncogenes and tumor suppressor genes leads to dysregulated signal transduction that underlies the abnormal growth and proliferation of cancer cells. Signaling proteins that are centrally located in important cancer-associated signaling networks can serve as therapeutic targets [10].

2.1. Angiogenetic signaling pathways

Renal tumors are frequnently characterized by hypoxic conditions. Hypoxia and compensatory hyperactivation of angiogenesis are thought to be particularly important in renal tumors, given the highly vascularized nature and the specific association of mutation in VHL, a critical regulator of the hypoxic response. Hypoxic signaling is mediated by HIF. Increased expression of HIF target genes is implicated in promoting cancer, inducing both changes within the tumor and changes in the growth of adjacent endothelial cells to promote blood vessel growth. The expression level of VEGF in renal tumors is known to strongly correlate with microvessel density [10].

2.3. HGF/MET pathway

Changes in expression and activity of hepatocyte growth factor (HGF) and its receptor c-MET have been associated with renal tumors. HGF binding to MET leads to phosphorylation of two tyrosine residues at the C-terminus of MET, which leads to the recruitment of adapter proteins and activation of PI3K/AKT pathway to promote renal tumor growth and metastasis [12].

3. Biomarkers of response to sunitinib in renal tumors

3.1. Prognostic model

In the cytokine era, Motzer et al. [13] reported Memorial Sloan-Kettering Cancer Center (MSKCC) risk classification, which is based on data from 463 patients with advanced renal tumor who were treated with IFN-α cytokine therapy as first-line systemic therapy. The MSKCC risk classification extracted five variable risk factors for short survival: low Karnofsky performance status (PS) (< 80%), high lactate dehydrogenase (> 1.5 times the upper limit of normal), low serum hemoglobin, high corrected serum calcium (> 10 mg/dL), and time from initial renal tumor diagnosis to IFN-α therapy of less than one year. Each patient was assigned to one of three risk groups: those with zero risk factors (favorable risk), those with one or two risk factors (intermediate risk), and those with three or more risk factors (poor risk). The median time to death was 30, 14, and 5 months in the favorable, intermediate, and poor-risk groups, respectively [13]. These five risk criteria are now most frequently used prognostic model for patients with advanced renal tumor.

In the era of targeted therapy, Heng et al. [14] reported a new prognostic model that added platelet and neutrophil counts to the MSKCC model from a large multicenter study of 645 patients with metastatic renal tumor who were treated with targeted therapy. This study included three groups of patients: 396 patients treated with sunitinib, 200 patients treated with sorafenib, and 49 patients treated with bevacizumab. Four of the five adverse prognostic factors according to the MSKCC risk classification−low hemoglobin, high corrected serum calcium, low Karnofsky PS, and time from the initial renal tumor diagnosis to the start of treatment of less than one year−emerged as independent predictors of poor survival. Additionally, platelets greater than the upper limit of normal range, and neutrophils greater than the upper limit of normal range, emerged as independent adverse prognostic factors. MSKCC model with the addition of platelet and neutrophil counts can be incorporated into patient care of targeted therapies [14].

3.2. C-reactive protein

C-reactive protein (CRP), a non-specific inflammatory acute-phase protein, is a representative marker of systemic inflammatory response. CRP levels correlate with the production of proinflammatory cytokines, such as interleukin (IL) -6 [15], and with tumor progression [16, 17]. It has been recognized as an important prognostic marker in the cytokine era. Atzpodien et al. [16] reported data from 425 patients who received cytokine-based home therapy. On multivariate analysis, elevated CRP (≥ 1.1 mg/dL) was a poor prognostic factor, and Kaplan-Meier analysis demonstrated that patients with elevated CRP had significantly worse overall survival [16]. Casamassima et al. [17] reported that normal CRP (≤ 0.8 mg/dL) was the most independent prognostic factor for 110 patients treated with IL-2-based immunotherapy. Ramsey et al. [18] investigated the Glasgow Prognostic Score, which is based on a combination of hypoalbuminemia and elevated CRP (> 1.0 mg/dL). They found that CRP was independently associated with cancer-specific survival in 119 patients receiving immunotherapy [18]. Saito et al. [19] described that CRP kinetics have an impact on survival in patients with metastatic renal tumor treated with immunotherapy and/or metastasectomy. A decrease of CRP level during treatment predicts better prognosis in patients with metastatic renal tumor, and prolonged normalized CRP period is associated with prolonged survival [19].

Patients were grouped into two cohorts: those with normal CRP levels (≤ 0.30 mg/dL) and those with elevated CRP levels (> 0.30 mg/dL), according to the normal values provided by the manufacturer. The cohort with normal CRP comprised 10 males and 3 females (total 13 patients; 31.7%) with a median age of 63 years (range 46−77 years). The elevated CRP cohort comprised 20 males and 8 females (total 28 patients; 68.3%) with a median age of 64 years (range 36−80 years). MSKCC risk classification was favorable for 15.4% of the normal CRP cohort and intermediate for 86.4%. In contrast, in the elevated CRP cohort, MSKCC risk classification was favorable for 21.4%, intermediate for 46.4%, and poor for 32.2%. The difference in risk classification between the two groups was statistically significant (P = 0.0377). There were no statistically significant differences in any other pretreatment variables and tumor characteristics. The rate of partial response plus stable disease to treatment was 84.6% for the normal CRP cohort and 35.7% for the elevated CRP cohort. The higher response rate observed in the normal CRP cohort was statistically significant (P = 0.0022).

Normal CRP(≤ 0.30 mg/dL)

Elevated CRP(> 0.30 mg/dL)

P-value

13 (31.7%)

28 (68.3%)

Gender (n (%))

0.7118

Male

10 (76.9)

20 (71.4)

Female

3 (23.1)

8 (28.6)

Age (years)

0.5953

Median

63

64

Range

46−77

36−80

Mean ± standard deviation

64.8 ± 9.0

63.2 ± 9.1

ECOG PS (n (%))

0.0595

0

12 (92.3)

18 (64.3)

≥ 1

1 (7.7)

10 (35.7)

MSKCC risk classification (n (%))

0.0377

Favorable

2 (15.4)

6 (21.4)

Intermediate

11 (84.6)

13 (46.4)

Poor

0 (0)

9 (32.2)

Prior nephrectomy (n (%))

0.2767

Yes

12 (92.3)

22 (78.6)

No

1 (7.7)

6 (21.4)

T stage (n (%))

0.8187

T1 or T2

6 (46.2)

14 (50.0)

≥ T3

7 (53.8)

14 (50.0)

Grade (n (%))

0.6628

1 or 2

9 (69.2)

17 (60.7)

3

3 (23.1)

8 (28.6)

Prior immunotherapy (n)

0.2482

IFN-α

9

14

IL-2 and IFN-α

3

6

Prior targeted therapy (n)

0.8651

Sorafenib

5

10

Metastatic sites (n)

Lung

12

21

Bone

2

12

Lymph nodes

3

7

Brain

1

3

Pancreas

−

4

Adrenal

−

4

Skin

−

3

Kidney

−

2

Local

−

2

Liver

−

2

Prostate

1

−

No. metastatic sites (n (%))

0.1929

1

6 (46.1)

8 (28.6)

≥ 2

6 (46.1)

20 (71.4)

Treatment (n (%))

0.2122

First-line

3 (23.1)

13 (46.4)

Second-line

6 (46.1)

6 (21.4)

Third-line

4 (30.8)

9 (32.2)

Responses (n (%))

0.0022

Partial response plus stable disease

11 (84.6)

10 (35.7)

Table 2.

Patient characteristics grouped by CRP level

The median progression-free survival time for the elevated CRP cohort was 6.0 months. In contrast, the median progression-free survival time for the normal CRP cohort was significantly longer, at 19.0 months (log-rank P = 0.0361).

Figure 1.

CRP is a significant independent prognostic indicator for patients with advanced renal tumor treated with sunitinib. Pretreatment CRP level could be a useful biomarker for response to sunitinib treatment [20].

3.3. Selected adverse events

Sunitinib has been related a variety of adverse events, key notable clinical adverse events included diarrhea (61%), fatigue (54%), hypertension (30%), stomatitis (30%), HFS (29%), and asthenia (20%) [4]. Laboratory abnormalities also found that included leukopenia (78%), anemia (79%), increased creatinine (70%), and thrombocytopenia (68%) [4]. If adverse events depends on the degree of systemic exposure to sunitinib, on which clinical efficacy also depends, adverse events might be potential predictors of sunitinib efficacy [21]. Several authors have described the correlation between sunitinib responses and selected treatment-related adverse events.

3.3.1. Hypertension

Hypertension is commonly associated with targeted therapy. It develops when VEGF stimulates production of nitric oxide and prostacyclins in vascular endothelial cells [22, 23], vasodilatory mechanisms become inhibited, and peripheral vascular resistance increases, leading to increased blood pressure.

Rini et al. [24] demonstrated that sunitinib-associated hypertension is associated with improved clinical outcomes without clinically significant increases in hypertension-associated adverse events. This analysis included large pooled data from four clinical trilas of 4915 patients with metastatic renal tumor who were treated with sunitinib. Sunitinib-induced hypertension had significantly better outcomes than those without treatment-induced hypertension in the objective response rate (54.8% vs 8.7%), the median progression-free survival time (12.5 vs 2.5 months), and the median overall survival time (30.9 vs 7.2 months, P< 0.001 for all) [24].

Szmit et al. [26] reported that patients who developed hypertension related to sunitinib treatment experienced significantly longer progression-free survival time and overall survival time compared to those who did not hypertension (P< 0.00001). Patients treated with at least 3 antihypertensive agents experienced significantly longer progression-free survival time (P = 0.00002) and overall survival time (P = 0.00001) compared either with patients who received one or two medications or with patients who received no medications [26].

Rixe et al. [27] reported that appearance or worsening hypertension was found to be the single independent predictor of a better clinical response to sunitinib on multivariate analysis using logistic regression model (P = 0.009). Furthermore, grade 3 hypertension was correlated with a better outcome (P = 0.03). The appearance of hypertension, particularly grade 3, was associated with higher treatment response to sunitinib in metastatic renal tumors. Early and intensive antihypertensive therapy with the goal of maintaining the sunitinib use may improve response rate in those patients [27].

3.3.2. Hypothyroidism

Treatment-related hypothyroidism has been reported a useful predictor of progression-free survival for metastatic renal tumors undergoing treatment with sunitinib [28]. In the 52 patients with metastatic renal tumor treated with sunitinib, 13 patients (25.0%) developed hypothyroidism during treatment. Subclinical hypothyroidism was defined as serum TSH above the upper limit of normal, with total triiodothyronine (T3) and thyroxine (T4) within normal limits. Clinical hypothyroidism was defined as low serum T3 and T4 together with elevated TSH. Hypothyroidism was associated with a longer progression-free survival time (P = 0.032). Hormone replacement with 1-thyroxine did not have an influence on survival [28].

3.4. Others

Han et al. [29] reported the initial tumor enhancement on contrast-enhanced computed tomography (CT) could be useful as a clinical predictor during targeted therapy in 198 metastatic lesions of 46 patients. On multivariate analyses, tumor enhancement and enhancement pattern were associated with objective responses (P = 0.003 and 0.028, respectively). Additionally, tumor enhancement was associated with tumor size reduction (P = 0.004). On Cox proportional hazards models, only tumor enhancement was associated significantly with the time to size reduction and progression-free survival time (P = 0.03 and 0.015, respectively). Tumor enhancement on contrast-enhanced CT was associated with tumor size reduction, time to response, and time to progression of individual metastases in patients with metastatic renal tumor who received targeted therapy [29].

Kayani et al [30] revealed prognostic significance of 18F-fluorodeoxyglucose-positron emission tomography (FDG-PET)/CT as a biomarker of response to sunitinib. A total of 44 patients with newly diagnosed untreated metastatic renal tumor were enrolled in this study. 18F-FDG-PET/CT scans were conducted before, after 4 weeks, and after 16 weeks of sunitinib given. On multivariate analysis, a high SUVmax and an increased number of PET-positive lesions correlated with shorter overall survival. The early metabolic responses are associated with a pharmacodynamic effect of drug and it is not until later identification with acquired resistance occurs [30].

Yuasa et al. [31] reported that initial tumor size is inversely associated with the tumor reduction rate of individual metastatic sites and primary tumors in patients with metastatic renal tumor who underwent targeted therapy. A data from 139 metastatic and 16 primary lesions treated with targeted agents were analyzed. Both univariate and multivariate linear regression analyses revealed that only the initial tumor size was associated with the rate of reduction in individual tumors (P< 0.001) [31].

High visceral fat area could be a predictive biomarker from shorter survival in patients given first-line antiangiogenic agents including sunitinib for metastatic renal tumors [33]. In 113 study population, 46 patients received sunitinib as first-line therapy. Visceral fat area was measured retrospectively on the available CT scans performed before sunitinib initiation at the level of the umbilicus with the patient in the supine position. ImageJ software was used to measure pixels with densities in the -190 Hounsfield units to -30 Hounsfield units range to delineate the visceral compartment and to compute the cross-sectional area of each in cm2. On multivariate analysis, high visceral fat area was independently associated with shorter time to progression and overall survival. Visceral fat area measured before starting first-line targeted therapy is likely to be a simple predictive biomarker in patients with metastatic renal tumor [33].

Finally, hyponatremia seem to represent significant predictive factor for cancer-specific survival in metastatic renal tumors treated with targeted therapy as first-line therapy [34]. A total of 87 patients treated with targeted therapy including sunitinib, severe (≤ 134 mEq/L) and mild (135-137 mEq/L) hyponatremia was shown to be significantly associated with cancer-specific survival time (P = 0.001 and 0.013, respectively). In 38 patients treated wth sunitinib, 4 patients (10.5%) developed severe hyponatremia and 8 patients (21.1%) developed mild hyponatremia. Hyponatremia could be easily and readily determined and might be an important prognostic factor [34].

4. Conclusions

Candidate biomarkers to predict response to sunitinib have been shown. Among clinical factors, CRP is a significant independent prognostic indicator for sunitinib. Severe adverse events, hypertension and hypothyroidism also recognized as biomarkers of favorable efficacy. Additionally, tumor enhancement, SUVmax on FDG/PET-CT, tumor size, visceral fat area and hyponatremia have been revealed clinical significance of sunitinib responses. Although further investigation will be required, these biomarkers can be utilized to measure therapeutic response and design treatment strategies for advanced renal tumors treated with sunitinib.

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